The present disclosure relates to an electronic device comprising a wafer comprising a first upper surface having at least one first contact arranged thereon; and at least one die comprising a second upper surface having at least one second contact arranged thereon, and at least one first lateral surface orthogonal to the second upper surface, said first contact being coupled to said second contact by a connector comprising one first conductive pillar formed on said first contact of said wafer; one second conductive pillar formed on said second contact of said die; and at least one conductive ball positioned in contact with at least a first upper portion of said first pillar(s) and in contact with at least one second upper portion of said second pillar(s).

The present disclosure relates to an electronic device comprising a wafer comprising a first upper surface having at least one first contact arranged thereon; and at least one die comprising a second upper surface having at least one second contact arranged thereon, and at least one first lateral surface orthogonal to the second upper surface, said first contact being coupled to said second contact by a connector comprising one first conductive pillar formed on said first contact of said wafer; one second conductive pillar formed on said second contact of said die; and at least one conductive ball positioned in contact with at least a first upper portion of said first pillar(s) and in contact with at least one second upper portion of said second pillar(s).

Stacked die integrated circuit (IC) package employing an interposer for electrically coupling an upper stacked die(s) to a package substrate for package height reduction, and related fabrication methods. To reduce the height of the IC package while providing for stacked dies to be electrically coupled to a package substrate, the IC package includes an interposer. The stacked dies are disposed between the package substrate and the interposer. One or more wires are coupled (e.g., wire bonded) between the upper die and the interposer to provide an electrical connection between the upper die and the interposer. One or more electrical interconnects (e.g., conductive pillars) are coupled between the interposer and the package substrate to route electrical connections between the upper die and the package substrate. Thus, the upper die can be electrically coupled to the package substrate without requiring an additional clearance area above the upper die for wire bonds.

A semiconductor package includes a first semiconductor chip on a base chip, a second semiconductor chip on the first semiconductor chip in a first direction, each of the first and second semiconductor chips including a TSV and being electrically connected to each other via the TSV, dam structures on the base chip and surrounding a periphery of the first semiconductor chip, a first adhesive film between the base chip and the first semiconductor chip, a portion of the first adhesive film filling a space between the first semiconductor chip and the dam structures, a second adhesive film between the first semiconductor chip and the second semiconductor chip, a portion of the second adhesive film overlapping the dam structures in the first direction, and an encapsulant encapsulating a portion of each of the dam structures, the first semiconductor chip, and the second semiconductor chip.

A redistribution structure for a semiconductor device and a method of forming the same are provided. The semiconductor device includes a die encapsulated by an encapsulant, the die including a pad, and a connector electrically connected to the pad. The semiconductor device further includes a first via in physical contact with the connector. The first via is laterally offset from the connector by a first non-zero distance in a first direction. The first via has a tapered sidewall.

An electronic device includes an integrated circuit package including a die mounted on a die carrier, a mold structure at least partially encapsulating the mounted die, and a heat transfer chimney formed on the die. The heat transfer chimney extends at least partially through the mold structure to transfer heat away from the die. The heat transfer chimney is formed from a thermally conductive compound including thermally conductive nanoparticles.

An electronic device includes an integrated circuit package including a die mounted on a die carrier, a mold structure at least partially encapsulating the mounted die, and a heat transfer chimney formed on the die. The heat transfer chimney extends at least partially through the mold structure to transfer heat away from the die. The heat transfer chimney is formed from a thermally conductive compound including thermally conductive nanoparticles.

A semiconductor device includes a substrate having a plurality of pads on a surface of the substrate, a semiconductor chip that includes a plurality of metal bumps connected to corresponding pads on the substrate, a first resin layer between the surface of the substrate and the semiconductor chip, a second resin layer between the substrate and the semiconductor chip and between the first resin layer and at least one of the metal bumps, and a third resin layer on the substrate and above the semiconductor chip.

Semiconductor package includes interposer, dies, encapsulant. Each die includes active surface, backside surface, side surfaces. Backside surface is opposite to active surface. Side surfaces join active surface to backside surface. Encapsulant includes first material and laterally wraps dies. Dies are electrically connected to interposer and disposed side by side on interposer with respective backside surfaces facing away from interposer. At least one die includes an outer corner. A rounded corner structure is formed at the outer corner. The rounded corner structure includes second material different from first material. The outer corner is formed by backside surface and a pair of adjacent side surfaces of the at least one die. The side surfaces of the pair have a common first edge. Each side surface of the pair does not face other dies and has a second edge in common with backside surface of the at least one die.

A method includes forming a plurality of dielectric layers, which processes include forming a first plurality of dielectric layers having first thicknesses, and forming a second plurality of dielectric layers having second thicknesses smaller than the first thicknesses. The first plurality of dielectric layers and the second plurality of dielectric layers are laid out alternatingly. The method further includes forming a plurality of redistribution lines connected to form a conductive path, which processes include forming a first plurality of redistribution lines, each being in one of the first plurality of dielectric layers, and forming a second plurality of redistribution lines, each being in one of the second plurality of dielectric layers.